"""Semantic analysis of named tuple definitions.

This is conceptually part of mypy.semanal.
"""

from __future__ import annotations

import keyword
from collections.abc import Container, Iterator, Mapping
from contextlib import contextmanager
from typing import Final, cast

from mypy.errorcodes import ARG_TYPE, ErrorCode
from mypy.exprtotype import TypeTranslationError, expr_to_unanalyzed_type
from mypy.messages import MessageBuilder
from mypy.nodes import (
    ARG_NAMED_OPT,
    ARG_OPT,
    ARG_POS,
    MDEF,
    Argument,
    AssignmentStmt,
    Block,
    CallExpr,
    ClassDef,
    Context,
    Decorator,
    EllipsisExpr,
    Expression,
    ExpressionStmt,
    FuncBase,
    FuncDef,
    ListExpr,
    NamedTupleExpr,
    NameExpr,
    PassStmt,
    PlaceholderNode,
    RefExpr,
    Statement,
    StrExpr,
    SymbolTable,
    SymbolTableNode,
    TempNode,
    TupleExpr,
    TypeInfo,
    TypeVarExpr,
    Var,
    is_StrExpr_list,
)
from mypy.options import Options
from mypy.semanal_shared import (
    PRIORITY_FALLBACKS,
    SemanticAnalyzerInterface,
    calculate_tuple_fallback,
    has_placeholder,
    set_callable_name,
)
from mypy.types import (
    TYPED_NAMEDTUPLE_NAMES,
    AnyType,
    CallableType,
    LiteralType,
    TupleType,
    Type,
    TypeOfAny,
    TypeType,
    TypeVarId,
    TypeVarLikeType,
    TypeVarType,
    UnboundType,
    has_type_vars,
)
from mypy.util import get_unique_redefinition_name

# Matches "_prohibited" in typing.py, but adds __annotations__, which works at runtime but can't
# easily be supported in a static checker.
NAMEDTUPLE_PROHIBITED_NAMES: Final = (
    "__new__",
    "__init__",
    "__slots__",
    "__getnewargs__",
    "_fields",
    "_field_defaults",
    "_field_types",
    "_make",
    "_replace",
    "_asdict",
    "_source",
    "__annotations__",
)

NAMEDTUP_CLASS_ERROR: Final = (
    'Invalid statement in NamedTuple definition; expected "field_name: field_type [= default]"'
)

SELF_TVAR_NAME: Final = "_NT"


class NamedTupleAnalyzer:
    def __init__(
        self, options: Options, api: SemanticAnalyzerInterface, msg: MessageBuilder
    ) -> None:
        self.options = options
        self.api = api
        self.msg = msg

    def analyze_namedtuple_classdef(
        self, defn: ClassDef, is_stub_file: bool, is_func_scope: bool
    ) -> tuple[bool, TypeInfo | None]:
        """Analyze if given class definition can be a named tuple definition.

        Return a tuple where first item indicates whether this can possibly be a named tuple,
        and the second item is the corresponding TypeInfo (may be None if not ready and should be
        deferred).
        """
        for base_expr in defn.base_type_exprs:
            if isinstance(base_expr, RefExpr):
                self.api.accept(base_expr)
                if base_expr.fullname in TYPED_NAMEDTUPLE_NAMES:
                    result = self.check_namedtuple_classdef(defn, is_stub_file)
                    if result is None:
                        # This is a valid named tuple, but some types are incomplete.
                        return True, None
                    items, types, default_items, statements = result
                    if is_func_scope and "@" not in defn.name:
                        defn.name += "@" + str(defn.line)
                    existing_info = None
                    if isinstance(defn.analyzed, NamedTupleExpr):
                        existing_info = defn.analyzed.info
                    info = self.build_namedtuple_typeinfo(
                        defn.name, items, types, default_items, defn.line, existing_info
                    )
                    defn.analyzed = NamedTupleExpr(info, is_typed=True)
                    defn.analyzed.line = defn.line
                    defn.analyzed.column = defn.column
                    defn.defs.body = statements
                    # All done: this is a valid named tuple with all types known.
                    return True, info
        # This can't be a valid named tuple.
        return False, None

    def check_namedtuple_classdef(
        self, defn: ClassDef, is_stub_file: bool
    ) -> tuple[list[str], list[Type], dict[str, Expression], list[Statement]] | None:
        """Parse and validate fields in named tuple class definition.

        Return a four tuple:
          * field names
          * field types
          * field default values
          * valid statements
        or None, if any of the types are not ready.
        """
        if len(defn.base_type_exprs) > 1:
            self.fail("NamedTuple should be a single base", defn)
        items: list[str] = []
        types: list[Type] = []
        default_items: dict[str, Expression] = {}
        statements: list[Statement] = []
        for stmt in defn.defs.body:
            statements.append(stmt)
            if not isinstance(stmt, AssignmentStmt):
                # Still allow pass or ... (for empty namedtuples).
                if isinstance(stmt, PassStmt) or (
                    isinstance(stmt, ExpressionStmt) and isinstance(stmt.expr, EllipsisExpr)
                ):
                    continue
                # Also allow methods, including decorated ones.
                if isinstance(stmt, (Decorator, FuncBase)):
                    continue
                # And docstrings.
                if isinstance(stmt, ExpressionStmt) and isinstance(stmt.expr, StrExpr):
                    continue
                statements.pop()
                defn.removed_statements.append(stmt)
                self.fail(NAMEDTUP_CLASS_ERROR, stmt)
            elif len(stmt.lvalues) > 1 or not isinstance(stmt.lvalues[0], NameExpr):
                # An assignment, but an invalid one.
                statements.pop()
                defn.removed_statements.append(stmt)
                self.fail(NAMEDTUP_CLASS_ERROR, stmt)
            else:
                # Append name and type in this case...
                name = stmt.lvalues[0].name
                items.append(name)
                if stmt.type is None:
                    types.append(AnyType(TypeOfAny.unannotated))
                else:
                    # We never allow recursive types at function scope. Although it is
                    # possible to support this for named tuples, it is still tricky, and
                    # it would be inconsistent with type aliases.
                    analyzed = self.api.anal_type(
                        stmt.type,
                        allow_placeholder=not self.api.is_func_scope(),
                        prohibit_self_type="NamedTuple item type",
                        prohibit_special_class_field_types="NamedTuple",
                    )
                    if analyzed is None:
                        # Something is incomplete. We need to defer this named tuple.
                        return None
                    types.append(analyzed)
                # ...despite possible minor failures that allow further analysis.
                if name.startswith("_"):
                    self.fail(
                        f"NamedTuple field name cannot start with an underscore: {name}", stmt
                    )
                if stmt.type is None or hasattr(stmt, "new_syntax") and not stmt.new_syntax:
                    self.fail(NAMEDTUP_CLASS_ERROR, stmt)
                elif isinstance(stmt.rvalue, TempNode):
                    # x: int assigns rvalue to TempNode(AnyType())
                    if default_items:
                        self.fail(
                            "Non-default NamedTuple fields cannot follow default fields", stmt
                        )
                else:
                    default_items[name] = stmt.rvalue
        if defn.keywords:
            for_function = ' for "__init_subclass__" of "NamedTuple"'
            for key in defn.keywords:
                self.msg.unexpected_keyword_argument_for_function(for_function, key, defn)
        return items, types, default_items, statements

    def check_namedtuple(
        self, node: Expression, var_name: str | None, is_func_scope: bool
    ) -> tuple[str | None, TypeInfo | None, list[TypeVarLikeType]]:
        """Check if a call defines a namedtuple.

        The optional var_name argument is the name of the variable to
        which this is assigned, if any.

        Return a tuple of two items:
          * Internal name of the named tuple (e.g. the name passed as an argument to namedtuple)
            or None if it is not a valid named tuple
          * Corresponding TypeInfo, or None if not ready.

        If the definition is invalid but looks like a namedtuple,
        report errors but return (some) TypeInfo.
        """
        if not isinstance(node, CallExpr):
            return None, None, []
        call = node
        callee = call.callee
        if not isinstance(callee, RefExpr):
            return None, None, []
        fullname = callee.fullname
        if fullname == "collections.namedtuple":
            is_typed = False
        elif fullname in TYPED_NAMEDTUPLE_NAMES:
            is_typed = True
        else:
            return None, None, []
        result = self.parse_namedtuple_args(call, fullname)
        if result:
            items, types, defaults, typename, tvar_defs, ok = result
        else:
            # Error. Construct dummy return value.
            if var_name:
                name = var_name
                if is_func_scope:
                    name += "@" + str(call.line)
            else:
                name = var_name = "namedtuple@" + str(call.line)
            info = self.build_namedtuple_typeinfo(name, [], [], {}, node.line, None)
            self.store_namedtuple_info(info, var_name, call, is_typed)
            if name != var_name or is_func_scope:
                # NOTE: we skip local namespaces since they are not serialized.
                self.api.add_symbol_skip_local(name, info)
            return var_name, info, []
        if not ok:
            # This is a valid named tuple but some types are not ready.
            return typename, None, []

        # We use the variable name as the class name if it exists. If
        # it doesn't, we use the name passed as an argument. We prefer
        # the variable name because it should be unique inside a
        # module, and so we don't need to disambiguate it with a line
        # number.
        if var_name:
            name = var_name
        else:
            name = typename

        if var_name is None or is_func_scope:
            # There are two special cases where need to give it a unique name derived
            # from the line number:
            #   * This is a base class expression, since it often matches the class name:
            #         class NT(NamedTuple('NT', [...])):
            #             ...
            #   * This is a local (function or method level) named tuple, since
            #     two methods of a class can define a named tuple with the same name,
            #     and they will be stored in the same namespace (see below).
            name += "@" + str(call.line)
        if defaults:
            default_items = {
                arg_name: default for arg_name, default in zip(items[-len(defaults) :], defaults)
            }
        else:
            default_items = {}

        existing_info = None
        if isinstance(node.analyzed, NamedTupleExpr):
            existing_info = node.analyzed.info
        info = self.build_namedtuple_typeinfo(
            name, items, types, default_items, node.line, existing_info
        )

        # If var_name is not None (i.e. this is not a base class expression), we always
        # store the generated TypeInfo under var_name in the current scope, so that
        # other definitions can use it.
        if var_name:
            self.store_namedtuple_info(info, var_name, call, is_typed)
        else:
            call.analyzed = NamedTupleExpr(info, is_typed=is_typed)
            call.analyzed.set_line(call)
        # There are three cases where we need to store the generated TypeInfo
        # second time (for the purpose of serialization):
        #   * If there is a name mismatch like One = NamedTuple('Other', [...])
        #     we also store the info under name 'Other@lineno', this is needed
        #     because classes are (de)serialized using their actual fullname, not
        #     the name of l.h.s.
        #   * If this is a method level named tuple. It can leak from the method
        #     via assignment to self attribute and therefore needs to be serialized
        #     (local namespaces are not serialized).
        #   * If it is a base class expression. It was not stored above, since
        #     there is no var_name (but it still needs to be serialized
        #     since it is in MRO of some class).
        if name != var_name or is_func_scope:
            # NOTE: we skip local namespaces since they are not serialized.
            self.api.add_symbol_skip_local(name, info)
        return typename, info, tvar_defs

    def store_namedtuple_info(
        self, info: TypeInfo, name: str, call: CallExpr, is_typed: bool
    ) -> None:
        self.api.add_symbol(name, info, call)
        call.analyzed = NamedTupleExpr(info, is_typed=is_typed)
        call.analyzed.set_line(call)

    def parse_namedtuple_args(
        self, call: CallExpr, fullname: str
    ) -> None | (tuple[list[str], list[Type], list[Expression], str, list[TypeVarLikeType], bool]):
        """Parse a namedtuple() call into data needed to construct a type.

        Returns a 6-tuple:
        - List of argument names
        - List of argument types
        - List of default values
        - First argument of namedtuple
        - All typevars found in the field definition
        - Whether all types are ready.

        Return None if the definition didn't typecheck.
        """
        type_name = "NamedTuple" if fullname in TYPED_NAMEDTUPLE_NAMES else "namedtuple"
        # TODO: Share code with check_argument_count in checkexpr.py?
        args = call.args
        if len(args) < 2:
            self.fail(f'Too few arguments for "{type_name}()"', call)
            return None
        defaults: list[Expression] = []
        rename = False
        if len(args) > 2:
            # Typed namedtuple doesn't support additional arguments.
            if fullname in TYPED_NAMEDTUPLE_NAMES:
                self.fail('Too many arguments for "NamedTuple()"', call)
                return None
            for i, arg_name in enumerate(call.arg_names[2:], 2):
                if arg_name == "defaults":
                    arg = args[i]
                    # We don't care what the values are, as long as the argument is an iterable
                    # and we can count how many defaults there are.
                    if isinstance(arg, (ListExpr, TupleExpr)):
                        defaults = list(arg.items)
                    else:
                        self.fail(
                            "List or tuple literal expected as the defaults argument to "
                            "{}()".format(type_name),
                            arg,
                        )
                elif arg_name == "rename":
                    arg = args[i]
                    if isinstance(arg, NameExpr) and arg.name in ("True", "False"):
                        rename = arg.name == "True"
                    else:
                        self.fail(
                            f'Boolean literal expected as the "rename" argument to {type_name}()',
                            arg,
                            code=ARG_TYPE,
                        )
        if call.arg_kinds[:2] != [ARG_POS, ARG_POS]:
            self.fail(f'Unexpected arguments to "{type_name}()"', call)
            return None
        if not isinstance(args[0], StrExpr):
            self.fail(f'"{type_name}()" expects a string literal as the first argument', call)
            return None
        typename = args[0].value
        types: list[Type] = []
        tvar_defs = []
        if not isinstance(args[1], (ListExpr, TupleExpr)):
            if fullname == "collections.namedtuple" and isinstance(args[1], StrExpr):
                str_expr = args[1]
                items = str_expr.value.replace(",", " ").split()
            else:
                self.fail(
                    'List or tuple literal expected as the second argument to "{}()"'.format(
                        type_name
                    ),
                    call,
                )
                return None
        else:
            listexpr = args[1]
            if fullname == "collections.namedtuple":
                # The fields argument contains just names, with implicit Any types.
                if not is_StrExpr_list(listexpr.items):
                    self.fail('String literal expected as "namedtuple()" item', call)
                    return None
                items = [item.value for item in listexpr.items]
            else:
                type_exprs = [
                    t.items[1]
                    for t in listexpr.items
                    if isinstance(t, TupleExpr) and len(t.items) == 2
                ]
                tvar_defs = self.api.get_and_bind_all_tvars(type_exprs)
                # The fields argument contains (name, type) tuples.
                result = self.parse_namedtuple_fields_with_types(listexpr.items, call)
                if result is None:
                    # One of the types is not ready, defer.
                    return None
                items, types, _, ok = result
                if not ok:
                    return [], [], [], typename, [], False
        if not types:
            types = [AnyType(TypeOfAny.unannotated) for _ in items]
        processed_items = []
        seen_names: set[str] = set()
        for i, item in enumerate(items):
            problem = self.check_namedtuple_field_name(item, seen_names)
            if problem is None:
                processed_items.append(item)
                seen_names.add(item)
            else:
                if not rename:
                    self.fail(f'"{type_name}()" {problem}', call)
                # Even if rename=False, we pretend that it is True.
                # At runtime namedtuple creation would throw an error;
                # applying the rename logic means we create a more sensible
                # namedtuple.
                new_name = f"_{i}"
                processed_items.append(new_name)
                seen_names.add(new_name)

        if len(defaults) > len(items):
            self.fail(f'Too many defaults given in call to "{type_name}()"', call)
            defaults = defaults[: len(items)]
        return processed_items, types, defaults, typename, tvar_defs, True

    def parse_namedtuple_fields_with_types(
        self, nodes: list[Expression], context: Context
    ) -> tuple[list[str], list[Type], list[Expression], bool] | None:
        """Parse typed named tuple fields.

        Return (names, types, defaults, whether types are all ready), or None if error occurred.
        """
        items: list[str] = []
        types: list[Type] = []
        for item in nodes:
            if isinstance(item, TupleExpr):
                if len(item.items) != 2:
                    self.fail('Invalid "NamedTuple()" field definition', item)
                    return None
                name, type_node = item.items
                if isinstance(name, StrExpr):
                    items.append(name.value)
                else:
                    self.fail('Invalid "NamedTuple()" field name', item)
                    return None
                try:
                    type = expr_to_unanalyzed_type(type_node, self.options, self.api.is_stub_file)
                except TypeTranslationError:
                    self.fail("Invalid field type", type_node)
                    return None
                # We never allow recursive types at function scope.
                analyzed = self.api.anal_type(
                    type,
                    allow_placeholder=not self.api.is_func_scope(),
                    prohibit_self_type="NamedTuple item type",
                    prohibit_special_class_field_types="NamedTuple",
                )
                # Workaround #4987 and avoid introducing a bogus UnboundType
                if isinstance(analyzed, UnboundType):
                    analyzed = AnyType(TypeOfAny.from_error)
                # These should be all known, otherwise we would defer in visit_assignment_stmt().
                if analyzed is None:
                    return [], [], [], False
                types.append(analyzed)
            else:
                self.fail('Tuple expected as "NamedTuple()" field', item)
                return None
        return items, types, [], True

    def build_namedtuple_typeinfo(
        self,
        name: str,
        items: list[str],
        types: list[Type],
        default_items: Mapping[str, Expression],
        line: int,
        existing_info: TypeInfo | None,
    ) -> TypeInfo:
        strtype = self.api.named_type("builtins.str")
        implicit_any = AnyType(TypeOfAny.special_form)
        basetuple_type = self.api.named_type("builtins.tuple", [implicit_any])
        dictype = self.api.named_type("builtins.dict", [strtype, implicit_any])
        # Actual signature should return OrderedDict[str, Union[types]]
        ordereddictype = self.api.named_type("builtins.dict", [strtype, implicit_any])
        fallback = self.api.named_type("builtins.tuple", [implicit_any])
        # Note: actual signature should accept an invariant version of Iterable[UnionType[types]].
        # but it can't be expressed. 'new' and 'len' should be callable types.
        iterable_type = self.api.named_type_or_none("typing.Iterable", [implicit_any])
        function_type = self.api.named_type("builtins.function")

        literals: list[Type] = [LiteralType(item, strtype) for item in items]
        match_args_type = TupleType(literals, basetuple_type)

        info = existing_info or self.api.basic_new_typeinfo(name, fallback, line)
        info.is_named_tuple = True
        tuple_base = TupleType(types, fallback)
        if info.special_alias and has_placeholder(info.special_alias.target):
            self.api.process_placeholder(
                None, "NamedTuple item", info, force_progress=tuple_base != info.tuple_type
            )
        info.update_tuple_type(tuple_base)
        info.line = line
        # For use by mypyc.
        info.metadata["namedtuple"] = {"fields": items.copy()}

        # We can't calculate the complete fallback type until after semantic
        # analysis, since otherwise base classes might be incomplete. Postpone a
        # callback function that patches the fallback.
        if not has_placeholder(tuple_base) and not has_type_vars(tuple_base):
            self.api.schedule_patch(
                PRIORITY_FALLBACKS, lambda: calculate_tuple_fallback(tuple_base)
            )

        def add_field(
            var: Var, is_initialized_in_class: bool = False, is_property: bool = False
        ) -> None:
            var.info = info
            var.is_initialized_in_class = is_initialized_in_class
            var.is_property = is_property
            var._fullname = f"{info.fullname}.{var.name}"
            info.names[var.name] = SymbolTableNode(MDEF, var)

        fields = [Var(item, typ) for item, typ in zip(items, types)]
        for var in fields:
            add_field(var, is_property=True)
        # We can't share Vars between fields and method arguments, since they
        # have different full names (the latter are normally used as local variables
        # in functions, so their full names are set to short names when generated methods
        # are analyzed).
        vars = [Var(item, typ) for item, typ in zip(items, types)]

        tuple_of_strings = TupleType([strtype for _ in items], basetuple_type)
        add_field(Var("_fields", tuple_of_strings), is_initialized_in_class=True)
        add_field(Var("_field_types", dictype), is_initialized_in_class=True)
        add_field(Var("_field_defaults", dictype), is_initialized_in_class=True)
        add_field(Var("_source", strtype), is_initialized_in_class=True)
        add_field(Var("__annotations__", ordereddictype), is_initialized_in_class=True)
        add_field(Var("__doc__", strtype), is_initialized_in_class=True)
        if self.options.python_version >= (3, 10):
            add_field(Var("__match_args__", match_args_type), is_initialized_in_class=True)

        assert info.tuple_type is not None  # Set by update_tuple_type() above.
        shared_self_type = TypeVarType(
            name=SELF_TVAR_NAME,
            fullname=f"{info.fullname}.{SELF_TVAR_NAME}",
            # Namespace is patched per-method below.
            id=self.api.tvar_scope.new_unique_func_id(),
            values=[],
            upper_bound=info.tuple_type,
            default=AnyType(TypeOfAny.from_omitted_generics),
        )

        def add_method(
            funcname: str,
            ret: Type | None,  # None means use (patched) self-type
            args: list[Argument],
            is_classmethod: bool = False,
            is_new: bool = False,
        ) -> None:
            fullname = f"{info.fullname}.{funcname}"
            self_type = shared_self_type.copy_modified(
                id=TypeVarId(shared_self_type.id.raw_id, namespace=fullname)
            )
            if ret is None:
                ret = self_type
            if is_classmethod or is_new:
                first = [Argument(Var("_cls"), TypeType.make_normalized(self_type), None, ARG_POS)]
            else:
                first = [Argument(Var("_self"), self_type, None, ARG_POS)]
            args = first + args

            types = [arg.type_annotation for arg in args]
            items = [arg.variable.name for arg in args]
            arg_kinds = [arg.kind for arg in args]
            assert None not in types
            signature = CallableType(cast(list[Type], types), arg_kinds, items, ret, function_type)
            signature.variables = (self_type,)
            func = FuncDef(funcname, args, Block([]))
            func.info = info
            func.is_class = is_classmethod
            func.type = set_callable_name(signature, func)
            func._fullname = fullname
            func.line = line
            if is_classmethod:
                v = Var(funcname, func.type)
                v.is_classmethod = True
                v.info = info
                v._fullname = func._fullname
                func.is_decorated = True
                dec = Decorator(func, [NameExpr("classmethod")], v)
                dec.line = line
                sym = SymbolTableNode(MDEF, dec)
            else:
                sym = SymbolTableNode(MDEF, func)
            sym.plugin_generated = True
            info.names[funcname] = sym

        add_method(
            "_replace",
            ret=None,
            args=[Argument(var, var.type, EllipsisExpr(), ARG_NAMED_OPT) for var in vars],
        )
        if self.options.python_version >= (3, 13):
            add_method(
                "__replace__",
                ret=None,
                args=[Argument(var, var.type, EllipsisExpr(), ARG_NAMED_OPT) for var in vars],
            )

        def make_init_arg(var: Var) -> Argument:
            default = default_items.get(var.name, None)
            kind = ARG_POS if default is None else ARG_OPT
            return Argument(var, var.type, default, kind)

        add_method("__new__", ret=None, args=[make_init_arg(var) for var in vars], is_new=True)
        add_method("_asdict", args=[], ret=ordereddictype)
        add_method(
            "_make",
            ret=None,
            is_classmethod=True,
            args=[Argument(Var("iterable", iterable_type), iterable_type, None, ARG_POS)],
        )

        self_tvar_expr = TypeVarExpr(
            SELF_TVAR_NAME,
            info.fullname + "." + SELF_TVAR_NAME,
            [],
            info.tuple_type,
            AnyType(TypeOfAny.from_omitted_generics),
        )
        info.names[SELF_TVAR_NAME] = SymbolTableNode(MDEF, self_tvar_expr)
        return info

    @contextmanager
    def save_namedtuple_body(self, named_tuple_info: TypeInfo) -> Iterator[None]:
        """Preserve the generated body of class-based named tuple and then restore it.

        Temporarily clear the names dict so we don't get errors about duplicate names
        that were already set in build_namedtuple_typeinfo (we already added the tuple
        field names while generating the TypeInfo, and actual duplicates are
        already reported).
        """
        nt_names = named_tuple_info.names
        named_tuple_info.names = SymbolTable()

        yield

        # Make sure we didn't use illegal names, then reset the names in the typeinfo.
        for prohibited in NAMEDTUPLE_PROHIBITED_NAMES:
            if prohibited in named_tuple_info.names:
                if nt_names.get(prohibited) is named_tuple_info.names[prohibited]:
                    continue
                ctx = named_tuple_info.names[prohibited].node
                assert ctx is not None
                self.fail(f'Cannot overwrite NamedTuple attribute "{prohibited}"', ctx)

        # Restore the names in the original symbol table. This ensures that the symbol
        # table contains the field objects created by build_namedtuple_typeinfo. Exclude
        # __doc__, which can legally be overwritten by the class.
        for key, value in nt_names.items():
            if key in named_tuple_info.names:
                if key == "__doc__":
                    continue
                sym = named_tuple_info.names[key]
                if isinstance(sym.node, (FuncBase, Decorator)) and not sym.plugin_generated:
                    # Keep user-defined methods as is.
                    continue
                # Do not retain placeholders - we'll get back here if they cease to
                # be placeholders later. If we keep placeholders alive, they may never
                # be reached again, making it to cacheable symtable.
                if not isinstance(sym.node, PlaceholderNode):
                    # Keep existing (user-provided) definitions under mangled names, so they
                    # get semantically analyzed.
                    r_key = get_unique_redefinition_name(key, named_tuple_info.names)
                    named_tuple_info.names[r_key] = sym
            named_tuple_info.names[key] = value

    # Helpers

    def check_namedtuple_field_name(self, field: str, seen_names: Container[str]) -> str | None:
        """Return None for valid fields, a string description for invalid ones."""
        if field in seen_names:
            return f'has duplicate field name "{field}"'
        elif not field.isidentifier():
            return f'field name "{field}" is not a valid identifier'
        elif field.startswith("_"):
            return f'field name "{field}" starts with an underscore'
        elif keyword.iskeyword(field):
            return f'field name "{field}" is a keyword'
        return None

    def fail(self, msg: str, ctx: Context, code: ErrorCode | None = None) -> None:
        self.api.fail(msg, ctx, code=code)
